Light emitting element and lighting instrument

ABSTRACT

The present invention provides a white light emitting diode for emitting white light with warmness at a higher luminance, and an intermediate color light emitting diode satisfying light emission with diversified color tones at a higher luminance. A fluorescent material which emits yellowish red or red light and has a CaAlSiN 3  crystal phase including, dissolved therein in a solid state, one or more element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu. The fluorescent material is mixed with another fluorescent material emitting green, yellowish green, or yellow light, and the mixed phosphor is combined with a semiconductor light emitting element for emitting bluish purple or blue light, to fabricate a white light emitting diode which efficiently emits a warm white light with a high efficiency.

TECHNICAL FIELD

The present invention relates to a high-luminance white light emitting diode for lighting, an intermediate color light emitting diode for special decorative lighting, and lighting instruments adopting them.

BACKGROUND ART

There have been recently and extensively investigated white light emitting diodes each provided by combining a blue light emitting diode element and a blue-light absorbing/yellow-light emitting phosphor, and have been proposed and presented in various literatures including patent-related references (see patent-unrelated reference 1, and patent-related references 1 through 5, for example). Recently, lighting instruments, lighting equipments, and lighting apparatuses based on the aforementioned combination have been put into practical use.

Known as one of phosphors so frequently used in the above applications, is a yttrium/aluminum/garnet based phosphor activated by cerium, represented by a general formula (Y, Gd)₃(Al, Ga)₅O₁₂:Ce³⁺. However, the white light emitting diode comprising a blue light emitting diode element and a yttrium/aluminum/garnet based phosphor has a feature to emit bluish white light due to lack of a red component, thereby problematically exhibiting deviation in a color rendering property.

Meanwhile, lighting techniques have been diversified in usages, usage schemes, and needs, thereby demanding diversified color tone designs including realization of not only white color having a higher color temperature in the aforementioned lighting techniques utilizing light emitting diodes, but also white colors having various color temperatures such as seen in conventional ordinary lighting instruments, respectively. For example, there has been sought for a white light emitting diode for achieving a white color which provides warmness and is called an “incandescent color”. Under such circumstances, there has been investigated a white light emitting diode including two kinds of mixed and dispersed phosphors, such that a red component lacking in case of a yttrium/aluminum/garnet based phosphor is compensated for by an additional red phosphor.

Such a white light emitting diode has been proposed in a patent-related reference 4 (“white light emitting element”), a patent-related reference 5 (“nitride phosphor and production method thereof”), and the like. However, the above-described problem has not been fully solved even by the inventions proposed in them, which is away from a situation where the needs demanding diversified color schemes and chromaticities are fully dealt with, while such proposals are also insufficient in emission intensity, thereby still exhibiting a problem to be solved. Namely, the invention described in the patent-related reference 4 has a problem in that a red phosphor to be used therein contains Cd, i.e., a cadmium element. In this respect, it has been recently conducted to eliminate cadmium and a cadmium-including compound from usage, based on anxiety about environmental pollution, in a manner to alternatively use a substance free of cadmium. It will be thus desirable to make the same approach also in design of fluorescent material in view of the above consideration, since usage of cadmium appears to be undesirable.

Further, red-light emitting phosphors described in a patent-related reference 5 and exemplarily represented by Ca_(1.97)Si₅N₈:Eu_(0.03), are not problematic in that the phosphors include no elements like cadmium which are concerned about environmental pollution, but the phosphors are insufficient in emission intensity, so that further improvement is desired therefor. Moreover, the technical concepts described in the patent-related references 4 and 5 have merely and exclusively referred to realization of white color. Lighting techniques are diversified in usage as mentioned above, and decorative effects are also demanded. Thus, diversified color tones and tints are demanded, thereby in turn demanding various light sources for preparing and realizing color tones therefor. Namely, such needs have not been satisfied by white light emitting diodes only, so that there has been desired realization of light emitting diodes of various intermediate colors. Additionally, it has been also desired to extend a chromaticity range as wide as possible from a desired color tone so as to attain a sufficient color tone expression.

[Patent-unrelated reference 1] M. Yamada et al, Jpn. J. Appl. Phys., vol. 42 (2003), pp. L20-23

[Patent-related reference 1] JP-2900928

[Patent-related reference 2] JP-2927279

[Patent-related reference 3] JP-3364229

[Patent-related reference 4] JP-A-10-163535

[Patent-related reference 5] JP-A-2003-321675

DISCLOSURE OF THE INVENTION Problem to be Solved by the Invention

The above-described related art are disadvantageously lacking in diversified color tones, chromaticities, light emitting intensities, and the like, and are disadvantageous due to adverse effects to the environment, and it is thus an object of the present invention to provide light emitting diodes free of such problems, white light emitting diodes for emitting white light with warmness, and intermediate color light emitting diodes satisfying light emission in diversified color tones. In more detail, it is an object of the present invention to provide a white light emitting diode for emitting white light with warmness at a higher efficiency, by designing a material for a novel red phosphor comprising components free of possibility of environmental pollution and having a higher light-emission efficiency, and by combining the phosphor with a blue light emitting diode to adopt the combination. It is a further object of the present invention to provide an intermediate color light emitting diode for enabling arbitrary selection of a light emission color from among a wider chromaticity range.

Means for Solving the Problem

To achieve the above objects, the present inventors have earnestly investigated and consequently succeeded in fabricating and providing a white light emitting diode for emitting white light with warmness at a higher efficiency, and a diode for emitting light in a color tone arbitrarily selectable from among a wide chromaticity range such as a so-called intermediate color light emitting diode, by: adopting a phosphor according to an invention of a Japanese patent application (No. 2003-394855) previously developed by the present inventors, i.e., a fluorescent material for emitting yellowish red light or red light, which comprises a CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one kind or two or more kinds of element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu; mixing, into the phosphor, a fluorescent material at a predetermined ratio which emits green, yellowish green or yellow light; and combining a semiconductor light emitting element for emitting bluish purple or blue light, with the mixedly obtained phosphor, in a manner to actually mount the phosphor near the semiconductor element so as to energize the semiconductor light emitting element to thereby emit light.

The present invention has been carried out based on the above success and knowledges, and the technical matters taken therein will be described in the following items (1) through (7), thereby succeeding in solving the above problems.

(1) A visible light emitting device, characterized in that the visible light emitting device includes at least:

a semiconductor light emitting element configured to emit bluish purple or blue light;

a support member formed with a depression for placing the semiconductor light emitting element therein, the depression having an inclined surface constituted as a visible wavelength light reflective surface;

terminals configured to supply electric power to the semiconductor light emitting element; and

a phosphor configured to absorb a part or the whole of light emitted from the light emitting element, and to emit fluorescence at a wavelength different from that of the absorbed light, the phosphor including X % of a first fluorescent material configured to emit green, yellowish green, or yellow light, and Y % of a second fluorescent material configured to emit yellowish red or red light, at a mixing ratio meeting a condition of 0≦X<100, 0<Y≦100, and 0<X+Y≦100,

wherein the second fluorescent material comprises a CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one kind or two or more kinds of element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu.

(2) The light emitting device of item (1), characterized in that the second fluorescent material contains at least Eu.

(3) The light emitting device of item (1) or (2), characterized in that the semiconductor light emitting element is a blue light emitting diode having a main emission wavelength of 380 nm to 485 nm,

the first fluorescent material is a phosphor powder having a main emission wavelength of 495 nm to 585 nm,

the second fluorescent material is a phosphor powder having a main emission wavelength of 585 nm to 780 nm, and

the phosphor powders are mixed, dispersed in a resin, and mounted to cover the blue light emitting diode element.

(4) A lighting apparatus characterized in that the lighting apparatus includes three or more light source units, each light source unit including at least one light emitting device,

the light emitting device including at least:

a semiconductor light emitting element configured to emit bluish purple or blue light;

a support member formed with a depression for placing the semiconductor light emitting element therein, the depression having an inclined surface constituted as a visible wavelength light reflective surface;

terminals configured to supply electric power to the semiconductor light emitting element; and

a phosphor configured to absorb a part or the whole of light emitted from the light emitting element, and to emit fluorescence at a wavelength different from that of the absorbed light, the phosphor including at least one of a first fluorescent material configured to emit green, yellowish green, or yellow light, and a second fluorescent material configured to emit yellowish red or red light,

wherein each of the light source units or each of the light emitting device has a mixing ratio of the first fluorescent material to the second fluorescent material, which mixing ratio is different from those of the other light source units or other light emitting devices, in a manner that different light emission colors are visible, site by site of the lighting apparatus.

(5) The lighting apparatus of item (4), characterized in that the light emitting device of any one of items (1) through (3) is used as the light emitting device.

(6) The lighting apparatus of item (5), characterized in that each light source unit is optically connected with a light guiding member including a scattering element.

(7) The lighting apparatus of item (6), characterized in that the scattering element comprises air bubbles, and the light guiding member is a rod-like member made of transparent resin.

EFFECT OF THE INVENTION

The above feature resides in adoption of a fluorescent material which is configured to emit yellowish red or red light and which comprises a CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one kind or two or more kinds of element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu, in a manner that the fluorescent material is mixed with another fluorescent material configured to emit green, yellowish green, or yellow light, and that the mixedly obtained phosphor is combined with a semiconductor light emitting element configured to emit bluish purple or blue light, thereby succeeding in fabricating a white light emitting diode for emitting white light with warmness at a high efficiency, with an extremely remarkable effect.

Further, the present invention enables arbitrary color tones by virtue of the above configuration, and thus has succeeded in fabricating and providing an intermediate color light emitting diode configured to emit intermediate color light, with an extremely remarkable significance. In this way, the present invention exhibits an exceptional effect such as achievement of a light emitting diode which has a wider chromaticity range and which is excellent in color rendering property as compared with a situation of adoption of the conventionally known red phosphor, so that the present invention is expected to be widely utilized in various usages including decorative usage from now on in a manner to largely contribute to development of the industry through the lighting technique.

Moreover, the light emitting diode of the present invention has a higher light-emission efficiency, and it is thus expected that the same directly realizes an energy-saving lighting instrument to thereby exhibit an exceptional effect.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a chromaticity diagram (CIE) of XYZ colorimetric system in conformity to JIS Z8701 and a chromaticity range of the present invention.

FIG. 2 is a graph of emission spectra of a first phosphor and a second phosphor as measured by a spectrophotofluorometer (exciting wavelength is 460 nm identically to a blue light emitting diode element used in embodiments).

FIG. 3 is a graph of excitation spectra of the first phosphor and the second phosphor as measured by a spectrophotofluorometer (emission monitor wavelengths are 543 nm and 653 nm which are light emission peak wavelengths of the phosphors, respectively).

FIG. 4 is a schematic view of a first embodiment mounted as a bullet-type light emitting diode lamp.

FIG. 5 is a graph of an emission spectrum of the light emitting diode of the first embodiment.

FIG. 6 is a schematic view of a second embodiment mounted as a chip-type light emitting diode lamp.

FIG. 7 is a schematic view of a third embodiment as a highly decorative lighting apparatus including a number of intermediate color light emitting diodes arranged in line to realize light emission in a gradation manner.

FIG. 8 is a graph of an emission spectrum of that light emitting diode lamp of a first lamp unit of the lighting apparatus of FIG. 7, which has a yellowish white chromaticity.

FIG. 9 is a graph of an emission spectrum of that light emitting diode lamp of a ninth lamp unit of the lighting apparatus of FIG. 7, which has a pale pink chromaticity.

BEST MODE FOR CARRYING OUT THE INVENTION

The present invention will be concretely described, based on the drawings, embodiments, and the like. In the present specification, the “second fluorescent material which emits yellowish red or red light” or the second fluorescent material “which comprises a CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one kind or two or more kinds of element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu”, are those developed by the present inventors and have been already disclosed in a Japanese patent application (No. 2003-394855). Namely, although the second fluorescent material “which emits yellowish red or red light” or “which comprises a CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one kind or two or more kinds of element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu” has been disclosed concerning its easy availability by disclosing its production method in the above-described Japanese patent application, the aspects of a production method and a preparation method will be also disclosed concretely in the embodiments to be described later in the present specification in a readily available manner, similarly to the above mentioned Japanese patent application.

Although the present invention will be concretely described based on embodiments and drawings, these embodiments are merely shown to aid in readily understanding the present invention, without limiting the present invention thereto.

There will be firstly and briefly described a structure and an operating principle of a light emitting diode lamp of the present invention. There is firstly prepared a blue light emitting semiconductor diode element; the light emitting semiconductor diode element is placed on a support member having a concave structure as schematically shown in FIG. 4; at least two electroconduction paths are connected to the diode element, so as to supply electric power thereto from the exterior; and the diode element is coated, from the above, with a first phosphor and a second phosphor which are dispersed in a transparent resin and mounted on the diode element in a manner to absorb the light emitted from the blue light emitting diode element and to emit fluorescences at wavelengths different from each other such as green and red in color, respectively. The light emitting diode lamp shown in FIG. 4 is called a bullet type, based on its external appearance shape.

FIG. 1 is a chromaticity diagram (see JIS Z8701) of XYZ colorimetric system of CIE, showing an emission spectrum when the light emitting diode lamp fabricated above is energized to emit light. In this graph, the point B (filled triangle) represents chromaticity coordinates of light emission of the blue light emitting diode element. The point G (filled circle) represents chromaticity coordinates of the first fluorescent material which is excited by blue light to emit green light. The point R (filled square) represents chromaticity coordinates of the second fluorescent material which is excited by blue light to emit red light. Relatedly, while the patent-related reference 4 has disclosed a technique for obtaining white light in a range where coordinates (x, y) are 0.21≦x≦0.48 and 0.19≦y≦0.45 by virtue of mixture of such blue, green, and red light, it is actually possible by the technique of the patent-related reference 4 to obtain light emission in an arbitrary intermediate color inside a triangle to be defined by connecting the three coordinate points B, G, and R.

According to the present invention, it is possible to achieve a light emitting diode capable of emitting light in various white colors and diversified intermediate colors, based on the principle explained with respect to the above emission spectrum. Note that the feature of the present invention substantially resides in that a novel material is adopted as the second fluorescent material thereby enabling light emission with high luminance. The second fluorescent material is derived from the previous Japanese patent application (No. 2003-394855) based on the invention of the present inventors, and is a novel fluorescent material comprising CaAlSiN₃ crystal activated by Eu. The novel second fluorescent material exhibits a higher luminance as compared with a conventionally well-known blue-light excited/red light emitting fluorescent material, and is a material exhibiting light emission at longer wavelengths. Emission spectra and excitation spectra of them are shown in FIG. 2 and FIG. 3, respectively.

In realizing an arbitrary intermediate color by mixing blue, green, and red, explanation is conducted by using a general chromaticity classification of system color names according to JIS Z8110. Desirable for blue are light sources which are in a range of bluish purple or blue in color. In case of adoption of a monochromatic light source, its wavelength range is to be 380 nm to 485 nm. Although shorter wavelengths seem to be desirable from a standpoint of enlarging an area of the triangle so as to widen an achievable chromaticity range, longer wavelengths are actually and rather felt to be brighter by people from a point of relative visibility property, so that wavelengths are to be determined in consideration of it as well.

In embodiments to be described later, there is adopted a blue light emitting diode element having an emission center wavelength of 460 nm, from among commercially and readily available ones. In turn, although desirable for green are fluorescent materials within a wavelength range of 495 nm to 550 nm, fluorescent materials for emission of yellowish green or yellow light within a wavelength range of 550 nm to 585 nm will do in an embodiment which aims at realizing, not arbitrary intermediate colors, but white light with warmness only. In the embodiments to be described later, there is adopted a conventionally known yttrium/aluminum/garnet based phosphor powder.

Concerning red, although fluorescent materials are desirable which emit within a wavelength range of 610 nm to 780 nm for red, those may also be adopted for yellowish red color in a wavelength range of 585 nm to 610 nm. In the present invention, adopted as a red phosphor, is a phosphor powder (the method for obtaining it will be clarified in the embodiments to be described later) comprising a novel substance of CaAlSiN₃ crystal activated by Eu. Conventionally, there are no red fluorescent materials, which exhibit sufficient luminance by blue light excitation.

In the patent-related reference 4, chromaticity coordinates represented by R in FIG. 1 correspond to yellowish red or to a chromaticity near a boundary between yellowish red and red. Further, the patent-related reference 5 includes its embodiment 1, for example, having chromaticity coordinates of x=0.583 and y=0.406 which also correspond to yellowish red. Contrary, the embodiments of the present invention each include a CaAlSiN₃ crystal activated by Eu, which has a higher luminance and exhibits emission chromaticity of red by virtue of emission at a longer wavelength which is conventionally absent, and such an emission chromaticity corresponds to chromaticity coordinates of x=0.670 and y=0.327.

The white light emitting diode with warmness of the present invention fabricated by adopting such a fluorescent material, has a higher luminance as compared with one fabricated by the related art. Further, the intermediate color light emitting diode of the present invention fabricated by adopting such a fluorescent material, has a higher luminance and a widened range of expressible chromaticity, as compared with one fabricated by the related art. In this way, the present invention is apparently novel and inventive. Note that it is possible to mix three or more kinds of fluorescent materials, for an improved color rendering property.

The present invention will be concretely described, based on embodiments.

There have been prepared phosphors for three colors basically required for designing a white color diode, i.e., red phosphor, green phosphor, and blue phosphor.

[Preparation of Red Phosphor]

Firstly, used as a red phosphor was a nitride phosphor powder described in and according to the previous Japanese patent application (No. 2003-394855) and mainly including CaAlSiN₃ crystal phase. The preparation method was as follows. Used as a starting material powder were: a silicon nitride powder having an averaged particle size of 0.5 μm, an oxygen content of 0.93 wt %, and an a-type content of 92%; an aluminum nitride powder having a specific surface area of 3.3 m²/g and an oxygen content of 0.79%; a calcium nitride powder; and europium nitride synthesized by nitriding metal europium in ammonia. To obtain a composition represented by a composition formula Eu_(0.0005)Ca_(0.9995)AlSiN₃, there were weighed 34.0735 wt % of the silicon nitride powder, 29.8705 wt % of the aluminum nitride powder, 35.9956 wt % of the calcium nitride powder, and 0.06048 wt % of the europium nitride powder; these powders were mixed for 30 minutes by agate mortar and pestle; and the thus obtained mixture was molded by a metal mold by applying thereto a pressure of 20 Mpa, into a molded body having a diameter of 12 mm and a thickness of 5 mm.

Note that all steps of weighing, mixing, and molding the powders were operatively conducted within a glove box capable of maintaining a nitrogen environment including a moisture of 1 ppm or less and oxygen of 1 ppm or less. The molded body was placed in a crucible made of boron nitride, and set in a graphite resistance heating type of electric furnace. There was conducted a sintering operation in a manner to firstly bring a sintering atmosphere to vacuum by a diffusion pump, to heat the molded body from a room temperature up to 800° C. at a rate of 500° C./hour, to introduce, at 800° C., nitrogen at a purity of 99.999 vol % to thereby establish a pressure of 1 Mpa, and to elevate the temperature up to 1,800° C. at a rate of 500° C./hour, followed by holding for two hours at 1,800° C. After sintering, the obtained sintered body was pulverized by agate pestle and mortar into a powder, and there was conducted X-ray diffraction measurement of the powder by using Kα line of Cu, thereby confirming that it was a CaAlSiN₃ crystal phase, based on the obtained chart. This powder was measured by a spectrophotofluorometer F-4500 manufactured by Hitachi, Ltd., thereby obtaining an emission spectrum shown in FIG. 2 and an excitation spectrum shown in FIG. 3.

The photometer was calibrated by performing excitation correction with rhodamine B as a reference specimen, and then using a standard light source in conformity to NIST in U.S. In measuring an emission spectrum, there was adopted an exciting wavelength of 460 nm which was the same as the emission center wavelength of the blue light emitting diode element used in the embodiments. The emission spectrum was so broad having an emission peak wavelength of 653 nm as shown in FIG. 2. Obtained from the emission spectrum of FIG. 2 were chromaticity coordinates of x=0.670 and y=0.327, on a chromaticity diagram of XYZ colorimetric system of CIE, and its main wavelength (dominant wavelength) was 612 nm. This is in a range of “red” by a general chromaticity classification, according to system color names in annexed FIG. 1 of JIS Z8110.

As apparent from comparison with an emission spectrum of a conventionally known yttrium/aluminum/garnet based phosphor in FIG. 2, the red phosphor comprising the CaAlSiN₃ crystal phase including Eu dissolved therein in a solid state, exhibited such red light emission with a higher luminance by excitation of blue light at a wavelength of 460 nm, which has not been realized up to now. The excitation spectrum of FIG. 3 was measured by using an emission monitor wavelength of 653 nm corresponding to an emission peak wavelength. It is seen that excitation can be achieved with a high efficiency over a very wide range centered near 460 nm.

[Preparation of Green Phosphor]

There was used a conventionally known yttrium/aluminum/garnet based phosphor, which was commercially available as a green phosphor for CRT. FIG. 2 shows an emission spectrum and FIG. 3 shows an excitation spectrum, respectively, measured by the calibrated F-4500. The emission spectrum was measured at an exciting wavelength of 460 nm, and was so broad having an emission peak wavelength of 543 nm. Chromaticity coordinates obtained from the emission spectrum of FIG. 2 were x=0.422 and y=0.547, and the main wavelength was 563 nm. This is in a range of “yellowish green” by the general chromaticity classification, according to the system color names. The excitation spectrum of FIG. 3 was measured by using an emission monitor wavelength of 543 nm corresponding to an emission peak wavelength. Note that the green phosphor is not limited to this one, insofar as adapted to be excited by blue light and to emit light in any one of green, yellowish green, and yellow.

[Preparation of Blue Light Emitting Element]

Adopted as a blue light emitting element was a commercially available blue light emitting diode element having an emission center wavelength of 460 nm. Used here was a light emitting semiconductor diode element made of InGaN, comprising a substrate made of silicon carbide having electrodes on both sides, respectively. Note that the blue light emitting element may be a light emitting diode element comprising a substrate made of sapphire having two electrodes on one side. Further, it may be a light emitting element other than a light emitting diode, insofar as capable of emitting blue light to thereby excite each phosphor.

After the above preparation, the white light emitting diode of the present invention will be concretely described based on its design structure and fabrication process.

Embodiment 1

There was fabricated a so-called bullet-type white light emitting diode lamp (1) shown in FIG. 4.

It included two lead wires (2, 3), one (2) of which had a depression having a blue light emitting diode element (4) placed therein. The blue light emitting diode element (4) had a lower electrode electrically connected to a bottom surface of the depression by an electroconductive paste, and an upper electrode electrically connected to the other lead wire (3) via thin gold line (5). Mounted near the light emitting diode element (4) was a phosphor (7) which was obtained by mixing a first phosphor and a second phosphor and which was dispersed in a resin. The phosphors were dispersed in a first resin (6) which was transparent and which covered the whole of the blue light emitting diode element (4). Encapsulated in a second transparent resin (8) were the tip end of the lead wire including the depression, the blue light emitting diode element, and the first resin including the phosphors dispersed therein. The second transparent resin (8) was in a substantially column shape as a whole, and had a tip end portion of a curved surface in a lens shape, which is typically called a bullet type.

In this embodiment, the mixing ratio between the first phosphor powder and second phosphor powder was set to be 5:2, this mixed powder was blended into an epoxy resin at a concentration of 35 wt %, and the resultant resin was dropped at an appropriate amount by a dispenser, thereby forming the first resin (6) including the mixed phosphor (7) dispersed therein. The obtained chromaticity was x=0.338 and y=0.330, which was substantially white. FIG. 5 shows an emission spectrum of the white light emitting diode of the embodiment 1.

There will be next explained a producing procedure of the bullet type white light emitting diode of this first embodiment. Firstly, the blue light emitting diode element (4) is die bonded by an electroconductive paste onto the element placement depression of one (2) of the paired lead wires, to thereby electrically connect the lead wire to the lower electrode of the blue light emitting diode element and to fix the blue light emitting diode element (4). Next, the upper electrode of the blue light emitting diode element (4) is die bonded to the other of lead wires, thereby electrically connecting them to each other. Previously mixed with each other at a mixing ratio of 5:2 are the first green phosphor powder and the second red phosphor powder, and this mixed phosphor powder is mixed into an epoxy resin at a concentration of 35 wt %. Next, the resultant resin is coated in an appropriate amount onto the depression by a dispenser to cover the blue light emitting diode element, and then cured to form the first resin (6). Finally, the tip end of the lead wire including the depression, the blue light emitting diode element, and the first resin including the phosphors dispersed therein, are wholly encapsulated in the second resin by a casting method. Although the same epoxy resin was used for the first resin and second resin in this embodiment, it is possible to adopt another resin such as a silicone resin, or a transparent material such as glass. It is desirable to select a material which is less in degradation due to ultraviolet light.

Embodiment 2

There was fabricated a chip-type white light emitting diode lamp (21) to be mounted on a substrate. Its configuration is shown in FIG. 6. It included a white alumina ceramic substrate (29) having a higher reflectivity to visible light, and, two lead wires (22, 23) fixed thereto, and the lead wires each included one end located at substantially the center position of the substrate, and the other end drawn out to the exterior to form an electrode to be soldered to an electric substrate upon mounting thereto. Placed onto and fixed to the one end of one (22) of the lead wires, was a blue light emitting diode element (24) so as to be located at the central portion of the substrate. The blue light emitting diode element (24) had a lower electrode electrically connected to the lead wire thereunder by an electroconductive paste, and an upper electrode electrically connected to the other lead wire (23) by a thin gold line (25).

Mounted near the light emitting diode element was a resin including a phosphor (27) which was dispersed therein and which was obtained by mixing a first resin and a second phosphor with each other. The first resin (26) including the phosphor dispersed therein was transparent and covered the whole of the blue light emitting diode element (24). Further, fixed on the ceramic substrate was a wall surface member (30) in a shape having a hole at a central portion. As shown in FIG. 6, the wall surface member (30) had its central portion acting as the hole for accommodating therein the blue light emitting diode element (24) and the first resin (26) including the phosphor (27) dispersed therein, and had a portion which was faced to the center and which was formed into an inclined surface. This inclined surface was a reflective surface for forwardly directing light-beams, and had a curved shape to be determined in consideration of the reflected directions of light-beams. Further, at least the surface which constituted the reflective surface, was formed into a surface which was white in color or had metallic luster and which had a higher reflectivity to visible light. In this embodiment, the wall surface member was constituted of a white silicone resin (30). While the hole of the wall surface member at its central portion constitutes a depression as a final shape of the chip-type light emitting diode lamp, the depression is filled with a second transparent resin (28) in a manner to encapsulate all the blue light emitting diode element (24) and the first resin (26) including the phosphor (27) dispersed therein. Adopted as the first resin (26) and second resin (28) in this embodiment was the same epoxy resin. The mixing ratio between the first phosphor and second phosphor, the achieved chromaticity, and the like were substantially the same as those of the first embodiment. The producing procedure was substantially the same as that of the first embodiment, except for a step for fixing the lead wires (22, 23) and the wall surface member (30) to the alumina ceramic substrate (29).

Embodiment 3

There were adopted a number of bullet type light emitting diode lamps of the embodiment 1, to realize a highly decorative lighting apparatus (41) having an emission chromaticity varied in a gradation manner. FIG. 7 is a schematic view thereof. The lighting apparatus includes a laterally elongated upper support body (51), which is to be directly attached to a ceiling of a building or to be suspended therefrom by a chain or the like, thereby supporting the whole of the lighting apparatus (41). Accommodated in the support body (51) is an electric circuit of a light emitting diode lamp driving portion, which is supplied with an electric power from a mains-powered outside AC 100V electric-power source, thereby supplying an appropriate electric current to the light emitting diode lamps. The driving portion is connected to an electric-power source switch not shown and a dimmer dial not shown, thereby enabling the lighting electric-power source to be manually turned ON and OFF and the lighting emission intensity to be adjusted. The support body is connected with a plurality of lamp units (52). This embodiment includes nine units. Installed in each lamp unit are a number of bullet type light emitting diode lamps. In this embodiment, concentrically arranged in each lamp unit are 18 pieces of bullet type light emitting diode lamps. The light emitting diodes were fabricated with varied chromaticities, lamp unit by lamp unit.

18 pieces of light emitting diodes installed in the fifth central lamp unit, each include the first phosphor and the second phosphor mixed at a ratio of 5:2 in a manner to achieve its chromaticity of white of x=0.34 and y=0.33 similarly to the first embodiment and second embodiment. The first lamp unit at one end has a mixing ratio of 12:1 to achieve yellowish white having chromaticity coordinates of x=0.37 and y=0.42. The ninth lamp unit at the other end has a mixing ratio of 4:5 to achieve pale pink having chromaticity coordinates of x=0.38 and y=0.32. The intermediately located second, third, fourth, sixth, seventh, and eighth lamp units, are constituted to have stepwise varied mixing ratios to achieve chromaticities which are varied in a gradation manner, respectively.

In addition to the variation of mixing ratios of the first phosphor and second phosphor, the bullet type light emitting diode lamps were produced to achieve appropriate chromaticities by appropriately adjusting coating amounts upon coating the first resin. Arranged at a lower portion of each lamp unit is a light guiding member (53) including a scattering element, such that light from the associated lamp unit enters the light guiding member. Concretely, there was adopted a columnar member made of transparent resin appropriately including air bubbles therein. In this way, there was achieved a highly decorative lighting apparatus, an aurora being imaged, which adopts intermediate color light emitting diode lamps with a higher luminance.

INDUSTRIAL APPLICABILITY

Recently, there have been rapidly and widely used white light emitting diodes for lighting each utilizing a blue light emitting diode element and phosphors. It is apparent that the present invention can be directly used in this field of art, and it is expected that the present invention is remarkably utilized since the present invention enables white color lighting with warmness at a higher luminance, and enables design of diversified color schemes and chromaticities which have not been conventionally provided, thereby enabling desired intermediate colors to be created. 

1. A visible light emitting device, comprising at least: a semiconductor light emitting element configured to emit bluish purple or blue light; a support member formed with a depression for placing said semiconductor light emitting element therein, said depression constituted as a visible wavelength light reflective surface; terminals configured to supply electric power to said semiconductor light emitting element; and a phosphor configured to absorb a part or the whole of light emitted from said light emitting element, and to emit fluorescence at a wavelength different from that of the absorbed light, the phosphor including X % of a first fluorescent material configured to emit green, yellowish green, or yellow light, and Y % of a second fluorescent material configured to emit yellowish red or red light, at a mixing ratio meeting a condition of 0≦X<100, 0<Y≦100, and 0<X+Y≦100, wherein said second fluorescent material comprises a CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one or more element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu.
 2. The light emitting device of claim 1, wherein said second fluorescent material contains at least Eu.
 3. The light emitting device to emit arbitrary colors of claim 1, wherein said semiconductor light emitting element is a blue light emitting diode having a main emission wavelength of 380 nm to 485 nm.
 4. A lighting apparatus, comprising three or more light source units, each light source unit including at least one light emitting device, said light emitting device including at least: a semiconductor light emitting element configured to emit bluish purple or blue light; a support member formed with a depression for placing said semiconductor light emitting element therein, said depression constituted as a visible wavelength light reflective surface; terminals configured to supply electric power to said semiconductor light emitting element; and a phosphor configured to absorb a part or the whole of light emitted from said light emitting element, and to emit fluorescence at a wavelength different from that of the absorbed light, the phosphor including at least one of a first fluorescent material configured to emit green, yellowish green, or yellow light, and a second fluorescent material mainly including CaAlSiN₃ crystal phase and configured to emit yellowish red or red light, wherein each of said light source units or each of said light emitting device has a mixing ratio of said first fluorescent material to said second fluorescent material, which mixing ratio is different from those of the other light source units or other light emitting devices, in a manner that different light emission colors are visible, site by site of said lighting apparatus.
 5. The lighting apparatus of claim 4, wherein the phosphor includes X % of said first fluorescent material, and Y % of said second fluorescent material, at a mixing ratio meeting a condition of 0≦X<100, 0<Y≦100, and 0<X+Y≦100, and wherein said second fluorescent material comprises said CaAlSiN₃ crystal phase including, dissolved therein in a solid state, one or more kinds of element(s) selected from Mn, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu.
 6. The lighting apparatus of claim 5, wherein each light source unit is optically connected with a light guiding member including a scattering element.
 7. The lighting apparatus of claim 6, wherein said scattering element comprises air bubbles, and said light guiding member is a rod-like member made of transparent resin.
 8. The light emitting device to emit arbitrary colors of claim 1, wherein said semiconductor light emitting element is a light emitting semiconductor diode element made of InGaN.
 9. The light emitting device to emit arbitrary colors of claim 1, wherein said semiconductor light emitting element is a light emitting semiconductor diode element comprising a substrate made of sapphire.
 10. The light emitting device to emit arbitrary colors of claim 1, wherein said first fluorescent material is a phosphor having a main emission wavelength of 495 nm to 585 nm.
 11. The light emitting device to emit arbitrary colors of claim 10, wherein said first fluorescent material is a yttrium/aluminum/garnet based phosphor.
 12. The light emitting device to emit arbitrary colors of claim 1, wherein said second fluorescent material is a phosphor having a main emission wavelength in a range of “red” by a general chromaticity classification, according to system color names of JIS Z8110.
 13. The light emitting device to emit arbitrary colors of claim 1, wherein said phosphors are dispersed in a transparent material.
 14. The light emitting device to emit arbitrary colors of claim 13, wherein said transparent material is an epoxy resin, a silicone resin, or a glass. 